Physiology of vision Diapasone of the visible light Optic system of eyeball Cornea allows light to enter the eyeball. Aqueous humor fills anterior and posterior chambers in front of lens. Crystalline lens is a transparent elastic and biconcave lens, which refracts light and focuses it on retina. Vitreous body is a transparent gel enclosed by vitreous membrane, which fills eyeball behind lens. Aqueous humor circulation Ciliary processes in posterior chamber secrete aqueous fluid. It flows between the ligament of the lens and then through the pupil into the anterior chamber of the eye. Then fluid passes into the angle between the cornea and the iris. Through the meshwork of trabeculli aqueous humor enters the channel of Slemm, which empties into extraoccular veins. Functions of aqueous humor: 1) maintains intraoccular pressure; 2) maintains shape of eyeball; 3) acts as refractory medium; 4) supplies nutrition; 5) drains metabolic end products. Accommodation and its regulation Accommodation is adjustment of eye lens for various distances. Relaxation of ciliary muscle cause decrease of refractive power of eye lens and provides clear vision for long distance. Decrease of parasympathetic influence to ciliary muscle controls it. In case of parasympathetic stimulation of ciliary muscle, it contracts, lens ligament relax, lens get more spherical, refractive power increases and eye can see clear near objects. Retina up-close Light Stephen E. Palmer, 2002 Cones cone-shaped less sensitive operate in high light color vision Two types of light-sensitive receptors Rods rod-shaped highly sensitive operate at night gray-scale vision Inside the rod and the cone Physiological peculiarities of pigmented layer and photoreceptors. Light falls on retina on inner side i.e. on inner limiting membrane. It is a minute area of 1 mm in center of retina. It provides acute and detail vision. Central portion of macula called fovea centralis. This is composed entirely of cones. Pigmented layer of retina contains black pigment, i.e. melanin. It prevents light reflection through the globe of eyeball and stores vitamin A. Photochemical reactions in retina Outer segment of photoreceptors contain photochemicals. Inner segment contains nucleus, synaptic body and other organelles. Photochemicals are light-sensitive chemicals that decompose on exposure to light and excite nerve fibers leading from eye to central nervous system. Rhodopsin is present in rods. Scotopsin and 11- cis-retinal compose it. Iodopsin is photochemical pigment of cones. Photopsin and 11-cis-retinal compose it. Rhodopsin cycle: rhodopsin under the influence of light converts to prelumirhodopsin lumirhodopsin metaphodopsin I - metaphodopsin II opsin rhodopsin. Metarhodopsin II converts also to all-transretinal (vitamin A) (isomerases action) II cis-retinal rhodopsin. Central division of visual analyzer Impulses from retina pass to optic nerve optic chiasm (fibers from nasal halves of retina cross to opposite side) optic tracts synapse in lateral genicular body geniculocalcarine fibers pass through optic radiation or geniculocalcarine tract primary visual cortex in calcarine fissure or medial aspect of occipital lobe. Light and dark adaptation. If a person remains in bright light for a long time, photochamicals in rods and cones reduce to all-transretinal and opsins. Most all-transretinal converts to all- transretinol (vitamin A). So, sensitivity of eye to light gets decreased. This is light adaptation. If a person remains in dark for a long time, all vitamin A convert to 11-cis retinal and than to photochemicals. Sensitivity of eye to light gets increased. This is dark adaptation. Theories of color perception According to Jung-Helmgolc theory there are three types of cones for three fundamental colors: cones for red color contain erythrolab; cones for green color contain chlorolab; cones for blue color contain cyanolab. According to Gering theory there are couples of opponent colors: green red; yellow blue; white black. Subcortical neurons percept it due to on- and off- centers mechanism. Binocular vision Binocular vision provides detection of distance and three-dimensional appearance of object in front of eyes. This is due to central analysis of fields of vision from both eyes. Final visual image is formed in visual cortex.